Lanthanide chromite-based sofc anodes

ABSTRACT

A SOFC, with a solid electrolyte layer and at least one anode layer constituting a stratified structure. The anode layer incorporates a twice substituted lanthanide chromite, substituted by Sr on A sites and by Ni or Cu on B sites. The stratified structure comprises a composite layer comprising a major amount of the substituted lanthanide chromite and a minor amount of the material of the electrolyte layer.

[0001] The present invention concerns the use of substituted lanthanide chromites as anode materials for operating a SOFC. The invention also concerns a SOFC.

[0002] Fuel Cells are able to directly convert chemical energy to electrical energy, without any Carnot limitations. Hence their energy efficiencies are relatively high. Among the various types of fuel cells, Solid Oxide Fuel Cells (SOFC) are operated at high temperatures and in principle, can run on various fuels such as natural gas (primarily methane), LPG, naphtha and hydrogen. Like any other electrochemical cell, it has an electrolyte, a cathode (air side) and an anode (fuel side). SOFCs use a solid oxygen ion conducting electrolyte (for example, yttria stabilised zirconia, YSZ). The fuel is oxidised on the anode side and to effect the oxidation process, the electrolyte transports the required O²⁻ from the cathode side. SOFCs are able to generate both electricity and high quality heat, which may be used for space heating or combined power cycle applications. The most preferred fuel for SOFC operation is natural gas as the reaction free energy is high

CH₄+2O₂═CO₂+2H₂O, Δ_(r)G°_(800° C.)=−800.8 kJ/mol, deep oxidation  (1)

[0003] and in the state of the art this is not fed in directly to the anode, because of problems associated with the anode deactivation and coking. Hence either pure hydrogen or an externally reformed natural gas feed is used. The external reformer not only decreases the overall system efficiency, as some of the free energy is wasted

CH₄+H₂O═CO+3H₂,Δ_(r)G°_(800° C.)=−45.2 kJ/mol, steam reforming  (2)

[0004] but also increases the system cost and causes heat management constraints. Therefore, a direct methane fed SOFC is a highly desirable technological breakthrough.

[0005] Conventional solid oxide fuel cells (SOFC) are operated with pure hydrogen or partially to fully reformed natural gas. SOFC anodes are generally made of electrocatalytically active Ni-YSZ cermets ^(1, 2). Pure methane feeding on this anode leads to the detachment of Ni particles from the YSZ support and their encapsulation by carbon ³ leading to coking and deactivation. From energetic, operational and design considerations, SOFCs running on direct natural gas feed would be more attractive systems. However, in this case, several parameters influence the anode performance and stability. The anodes should withstand reduction at P_(O2) as low as 10⁻²⁴ atm, be compatible with the YSZ electrolyte, possess acceptable thermal expansion coefficient, conductivity and appropriate catalytic and electrocatalytic properties and inhibit carbon deposition. CH₄ oxidation has been studied over various perovskite oxides of the ABO₃ formula ⁴⁻⁸. Among these, only LaCrO₃ was reported to be stable at 1000° C. and very low P_(O2) of 10⁻²¹ atm ⁹.

[0006] In SOFC, lanthanum chromites were investigated for their potential use as interconnect materials for cell stacking. These materials are easily substituted on the A and B sites with alkali and transition metal elements respectively, which allows interesting modifications in their catalytic and electronic properties. In literature, many reports focus on the doping effect of alkali (Mg, Ca, Sr) as well as transition metal (Co, Ni) elements on the conductivity, sintering and stability behaviour of these materials ¹⁰⁻¹⁷. Less work is done on catalysis. Methane partial oxidation was attempted on substituted lanthanum chromites by different groups for their use as catalysts or as possible anodes in SOFC ¹⁸⁻²³. The testing conditions were however far from real SOFC conditions (partial oxidation instead of steam or CO₂ reforming) and only a couple of group reported a real SOFC test ²⁴⁻²⁶ with La_(0.7)Ca_(0.3)CrO₃ and La_(0.8)Ca_(0.23)CrO₃. Also, more recently, Primdahl et al. ²⁷ reported impedance spectroscopy studies on La_(0.8)Sr_(0.2)Cr_(0.97)V_(0.03)O₃ in H₂ at open circuit potential (OCV). These experiments indicated little reforming and direct oxidation ability of the base LC materials. Alternatively, in catalytic runs, Metcalfe et al. ²⁸ showed the dissociation of dry CH₄ which was inhibited by H₂O addition.

[0007] Calcium and/or strontium substituted lanthanum chromites were explored as alternative anodes to Ni-YSZ ²⁹. These materials were observed to inhibit coking but their overall electrocatalytic activity was found to be low under pure methane feed. Also, a degradation was observed and was related to a progressive reduction of the electrode as well as a topotactic reaction between excess Ca or Sr with YSZ.

[0008] It is therefore an object of the invention to develop a SOFC running on hydrocarbons, capable to be directly fed with gaseous hydrocarbon, in particular natural gas, i.e. primary methane, having a high conversion efficiency and improved lifetime.

[0009] The inventors attempted to apply different LaCrO₃ powders as electrodes for their use as anode in methane. Following experimental tests (powder characterisation (XRD, SEM, TEM, EDS) conductivity and catalytic tests), it was possible to choose appropriate compositions from different substituents (Mg, Ca, Sr, Mn, Fe, Co, Ni, Cu and Nb).

[0010] According to a first aspect, the invention proposes the use of a twice substituted lanthanide chromite as an anode material of a direct hydrocarbon fed, in particular methane fed SOFC, wherein said lanthanide chromite is substituted by Sr on A sites and by Ni or Cu on B sites.

[0011] Ni is a particularly preferred substituent for B sites. Copper (Cu) has been tested by the inventors as an anode material in its pure form or in combination with Ni. It has also been used as a composite with an oxide such as YSZ and ceria. Its activity towards CH₄ oxidation was very promising even though a constant electric load was necessary to maintain the cell stability for a long time.

[0012] The inventors found that the degradation reactions at the anode was inhibited when relatively low substitution levels were adopted. Therefore, the invention preferably proposes a use of a Sr and Ni substituted lanthanum chromite of formula La_(1-x)Sr_(x)Cr_(1-y)Ni_(y)O₃ with the proviso that:

[0013] 0.01<x<0.3 and

[0014] 0.01<y<0.5

[0015] and more preferably with the proviso that:

[0016] 0.1<x<0.2 and

[0017] 0.05<y<0.2.

[0018] A particularly preferred anode material is La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃.

[0019] According to another preferred embodiment of the invention, the lanthanide is Praseodymium. Praseodymium (Pr) is known to have an interesting catalytic activity when used as a cathode catalyst at the interface in SOFC and is known to be the most active catalyst among rare earth oxides. It has also been used by the inventors for CH₄ fed. SOFC anode applications and found to be very promising.

[0020] According to another aspect, the invention provides a SOFC comprising a solid electrolyte layer and at least one anode layer constituting a stratified structure, said anode layer incorporating an effective amount of a twice substituted lanthanide chromite, wherein said lanthanide chromite is substituted by Sr on A sites and by Ni or Cu on B sites and wherein said stratified structure comprises a composite layer incorporating a major amount of said subsituted lanthanide chromite and an minor amount of the material of said electrolyte layer. The selected chromite provides high conversion rates and a low surface degradation and the composite layer provides a good adhesion between the electrolyte layer and the anode.

[0021] Preferably, said stratified structure comprises at least one or more composite layer located at the interface of said anode with said electrolyte and a plurality of layers consisting of said lanthanide chromite.

[0022] Preferably, the composite layer comprises an amount of between 15 and 40% in weight of the electrolyte, in particular YSZ or ceria, and according to a particularly preferred embodiment about 20% in weight of said electrolyte.

[0023] According to a preferred process for making the SOFC of the invention, the anode layer is obtained by providing said substituted lanthanide chromite as a perovskite powder, depositing at least one layer comprising said perovskite powder on an electrolyte member like YSZ or ceria, thereby forming a stratified structure, and sintering said stratified structure at a temperature of between 1000° C. and 1300° C., in particular 1050° C. and 1200° C., more particularly at about 1100° C.

[0024] Other features and advantages of the invention will appear to those skilled in the art from the following detailed description of the preparation of a particularly preferred anode material, of experimental cells using the same and of comparative tests with anodes and SOFCs using anode materials of the prior art. This description is made in connection with the drawings, which show the following:

[0025]FIG. 1: schematic view of a cell showing the 8YSZ Kerafol electrolyte, the LSM and the Pt-mesh cathode, the Pt reference electrode and on the opposite side the LC anode. a: non-sealed, b: sealed, and c: symmetrical cell.

[0026]FIG. 2: schematic view of the non-sealed testing set-up (not on scale).

[0027]FIG. 3: schematic view of the sealed testing set-up (not on scale).

[0028]FIG. 4: schematic view of a symmetrical testing set-up (not on scale).

[0029]FIG. 5: 3 layered La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ anodes. Sintering temperature effect on the potential-current and power curves, in 3% H₂O, at a working temperature of 900° C., a: H₂ and b: CH₄, and 840° C., c: H₂. Sintering temperatures: (Δ,▴) 1200° C. (E2c), (□,▪) 1100° C. (E2d) and (∇,▾) 1050° C. (E2f). Closed symbols: potential current; open symbols: power density curves.

[0030]FIG. 6: 3 layered La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ anodes. Sintering temperature effect on the anode overpotential, in 3% H₂O, at a working temperature of a: 900° C., and b: 840° C. Sintering temperatures: (Δ,▴) 1200° C. (E2c), (□,▪), 1100° C. (E2d) and (∇,▾) 1050° C. (E2f). Closed symbols: H₂; open symbols: CH₄.

[0031]FIG. 7: 1 layered 55.7:44.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃+8YSZ, +3 layers La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ composite anodes. Sintering temperature effect on the potential-current and power curves, in 3% H₂O, at a working temperature of 900° C., a: H₂ and b: CH₄, and 840° C., c: H₂ and d: CH₄. Sintering temperatures: (Δ,▴) 1200° C. (E2b), (□,▪), 1100° C. (E2e) and (∇,▾) 1050° C. (E2g). Closed symbols: potential current; open symbols: power density curves.

[0032]FIG. 8: 1 layered 55.7:44.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃+8YSZ, +3 layers La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ composite anodes. Sintering temperature effect on the anode overpotential, in 3% H₂O, at a working temperature of a: 900° C., and b: 840° C. Sintering temperatures: (Δ,▴) 1200° C. (E2b) and (□,▪) 1100° C. (E2e). Closed symbols: H₂; open symbols: CH₄.

[0033]FIG. 9: SEM micrographs showing the morphology of different 3 layered La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ anodes, sintered at a: 1200° C. (E2c), b: 1100° C. (E2d) and c: 1050° C. (E2f).

[0034]FIG. 10: SEM micrographs showing the morphology of different 1 layered 55.7:44.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃+8YSZ, +3 layered La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ composite anodes, sintered at a: 1200° C. (E2b), b: 1100° C. (E2e) and c: 1050° C. (E2g). The composite La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃+8YSZ stands in the first 5 μm near the YSZ electrolyte.

[0035]FIG. 11: SEM micrographs of La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ (E2c) anode showing a: a topotactic change at the interface (in the X region), and b: an EDAX linescan analysis of the same region, indicating eventually the formation of a SrZrO₃ phase (there is an uncertainty in the quantitative analysis of Sr and Zr as their EDAX peaks overlap).

[0036]FIG. 12: La_(0.85)Sr_(0.15)SCr_(0.9)Mg_(0.1)O₃ anode (B21). Effect of the cell polarisation on the anode impedance at OCV. (∘) initial anode impedance, after H₂ introduction at 850° C.; (Δ) the same impedance after polarisation in H₂. Inset numbers mark each decay in frequency.

[0037]FIG. 13: Electrocatalysis on La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B21). The cell Rp decrease upon polarisation at 1010, 900, 800, 700, 600, 500 and 400 mV in H₂+3% H₂O, at 850° C. Inset numbers mark each decay in frequency.

[0038]FIG. 14: La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B21). Overpotential in humidified H₂ and CH₄, and in dry CO₂/CO (ratio≈0.14), at 850° C.

[0039]FIG. 15: La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B21). Overpotential effect on the series resistance, Re, at 850° C. H₂+3% H₂O.

[0040]FIG. 16: La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B21). Aging effect on the stability of the anode power and current density output. T=850° C., H₂+3% H₂O.

[0041]FIG. 17: La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B21). Polarisation effect on the rate limiting processes, R₁—C₁, R₂—C₂ and R₃—C₃. T=850° C., in H₂+3% H₂O.

[0042]FIG. 18: La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B21). H₂O effect on the impedance spectra in H₂, at OCV and 850° C. Inset numbers in % refer to the % of H₂O in H₂.

[0043]FIG. 19: La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B24).,Effect of the working temperature on the initial (before polarisation) OCV impedance spectra. a: H₂, b: CH₄, +3% H₂O. Inset numbers mark each decay in frequency.

[0044]FIG. 20: La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode, in the sealed configuration (B30, B37). a: OCV measurements as a function of the steam to carbon ratio (S/C) and temperature. The thermodynamic equilibria for different gases are also shown along with measured values for an Au electrode. b: Example of MS analysis. 8YSZ pellet of 110 μm, Re≈17.6 Ωcm2, 22 mA/cm² at short circuit in humidified H₂ with an OCV of 1089 mV.

[0045]FIG. 21: La_(0.85)Ca_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B20). MS analysis of the gas composition at the outlet of the sealed cell. Cell voltage effect on the CH₄ conversion at 850° C. The low current density is thought to stem from bad current collection in the free standing contacts. Re≈17.6 Ωcm², 8YSZ pellet of 110 μm and 30 mlN/min CH₄ flow.

[0046]FIG. 22: La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B21). Effect of the gas composition on the anode performance. In: H₂ and CH₄, +3% H₂O and dry CO₂/CO (ratio of 0.14), at 850° C.

[0047]FIG. 23: La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B21). Effect of the CO₂/CO ratio on the cell performance at 850° C. Fuel total rate of 200 ml/min.

[0048]FIG. 24: La_(0.85)Ca_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B29). Effect of the temperature on the anode performance in a: H₂ and b: CH₄, 3% H₂O.

[0049]FIG. 25: La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B21). H₂O effect on CH₄ oxidation at 850° C. (▴) 4.8% H₂O(S/C≈0.05) and () 10.4% H₂O(S/C≈0.116).

[0050]FIG. 26: SEM micrographs showing the morphology of different 1 layered 56:44 lanthanum chromite +8YSZ, +3 layered lanthanum chromite composite anodes, sintered at 1100° C. for 4 h. The thickness of the composite lanthanum chromite +8YSZ was 5 μm near the YSZ electrolyte. a: LaCrO₃ (E5f), b: La_(0.85)Sr_(0.15)CrO₃ (E5a), c: LaCr_(0.9)Cu_(0.1)O₃ (E5I) and d: LaCr_(0.9)Ni_(0.1)O₃ (E5e).

[0051]FIG. 27: 1 layered 56:44 LC:YSZ+3 layered LC composite anodes sintered at 1100° C./4 h. Substitutent effect on the potential-current and power curves, in 3% H₂O at 900° C., a: H₂ and b: CH₄, and 840° C., c: H₂ and d: CH₄. (+,x) LaCrO₃ (E5f), (♦,⋄) La_(0.85)Sr_(0.15)CrO₃ (E5a), (

,>) LaCr_(0.9)Cu_(0.1)O₃ (E5i) and (,∘) LaCr_(0.9)Ni_(0.1)O₃ (E5e). The La_(0.85)Sr_(0.15)CrO₃ anode performance is not fully shown, and is used to indicate the difference existing with the B-site substituted LCs.

[0052]FIG. 28: Evolution of the corrected electrolyte resistance, Re, on the anode side, showing an additional ohmic drop in the adhesive layer. The 150 μm thick 8YSZ Kerafol electrolyte is supposed to give an ohmic drop of 0.38 Ωcm² and 0.27 Ωcm² at 850° C. (∇) and 900° C. (Δ) respectively.

[0053]FIG. 29: 1 layered 56:44 LC:YSZ+3 layered LC composite anodes sintered at 1100° C./4 h. Substitutent effect on the overpotential curves, in 3% H₂O at 900° C., a: H₂ and b: CH₄, and 840° C., c: H₂ and d: CH₄. (+) LaCrO₃, (E5f), (♦) La_(0.85)Sr_(0.15)CrO₃ (E5a), (

) LaCr_(0.9)Co_(0.1)O₃ (E5i), (O) LaCr_(0.9)Ni_(0.1)O₃ (E5e) and () La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ (E2e).

[0054]FIG. 30: 1 layered 56:44 La_(0.85)Sr_(0.15)CrO₃+8YSZ, +3 layers La_(0.85)Sr_(0.15)CrO₃ composite anode (E5a), sintered at 1100° C. Potential-current curves in a: H₂ and b: CH₄, in 3% H₂O, at a working temperature of (Δ,▴) 900° C., and (∇,▾) 840° C.

[0055]FIG. 31: LaCr_(0.9)Mg_(0.1)O₃ anode (B41). Very low power output is obtained without an intermediate adhesive layer. T=830° C. in wet H₂.

[0056]FIG. 32: 1 layered 78.2:21.8 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃+8YSZ, +3 layered La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ composite anode (E7b), sintered at 1100° C. Potential-current curves in a: H₂ (at 874° C.) and b: CH₄, in 3% H₂O.

[0057]FIG. 33: 1 layered 78.2:21.8 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃+8YSZ, +3 layered La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ composite anode (E7b), sintered at 1100° C. a: The increase of the anode temperature as a function of the current density in H₂+3% H₂O at 874° C.; b: The temperature dependence of the anodic electrolyte resistance Re in CH₄, +3% H₂O.

[0058]FIG. 34: 1 layered 78.2:21.8 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃+8YSZ, +3 layered La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ composite anode (E7b), sintered at 1100° C. Overpotential curves in H₂ (at 874° C.) and CH₄, in 3% H₂O.

[0059]FIG. 35: 1 layered 55.7:44.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃+8YSZ+1 layered La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ composite anode (E7c). Stability of the system in H₂+3% H₂O at 900° C. Effect of time on the stability: (∘,) 47 min, (□,▪) 780 min (Δ,▴) 1148 min and (∇,▾) 2260 min.

[0060]FIG. 36: Slow decrease of the conductivity with time, when the gas atmosphere of the pellets of (Δ) LCaCNi and (∘) LCaCMg is switched from air to H₂+3% H₂O.

[0061]FIG. 37: La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ anode (B24). Arrhenius plot for the 2 processes in a-b. wet H₂ and c-d. in wet CH₄. (∇,▾) first process (R₁—C₁) and (Δ,▴) second process (R₂—C₂). n1: 0.53-0.65; n2: 0.57-0.7; L≈800 nH, maximum error 1.2-4%.

[0062]FIG. 38: Possible mechanism for the electrochemical reaction of methane on LCs. Formaldehyde, CH₂O, is reported to be formed in many cases in literature 58.

[0063] Powder Preparation

[0064] Different lanthanum chromite powders were prepared according to the formula La_(1-x)A_(x)Cr_(1-y)B_(y)O₃ through a modified citrate route ⁵, by dissolving the nitrate precursors (Fluka, >99% purity except for Cr(NO₃)₃.9H₂O from Acros, 99%) in 1M aqueous citric acid solution. Most of the water was removed by heating at 80-90° C. in vacuum. The gels obtained were pyrolized at 110° C. for 20 h, then at 200° C. for 2 h and the resulting powders were crushed to size by dry ball-milling. A high temperature calcination at 1100° C. was then necessary to get pure perovskites, as confirmed by X-ray powder diffraction ³¹ (note that the detection limit for XRD is of: ≈1%). The surface areas and particle size distributions of these powders varied between 1 and 3 m²/g and 0.8 and 2.6 μm respectively ³¹. In this study, Ca and Sr were used as an A-site substituent, whereas Mg, Mn, Fe, Co and Ni were incorporated on the B-site (Table 1). These powders were previously characterised by XRD, XPS, TEM-EDS and catalytic tests ³¹.

[0065] Slurry Preparation and Cell Fabrication

[0066] Terpineol-ethyl cellulose-based slurries were prepared with the proportion of 56.50:39.55:3.95 ceramic powder:terpineol:ethyl cellulose, using isopropanol as a solvent. The slurries were obtained by evaporating the solvent under mechanical stirring on a heated plate. Composite slurries of LCs (substituted LaCrO₃) with Tosoh 8YSZ (TZ-8Y) powders were also made using appropriate amounts of LCs and 8YSZ powders (Table 1). The LC-based pastes were then screen-printed on an 10% HF etched 3 cm×3 cm or circular (Ø≈2.2 cm) Kerafol or self made tape-casting tapes of 8YSZ electrolytes sintered at 1500° C./3 h, to form electrodes of 1 cm² (square tapes) or 0.38 cm² (circular tapes) area. A 5 min etching, at 60° C., was implemented in order to remove surface impurities ³³. The number of layers and their composition varied from sample to sample (Table 1). As current collector, an Au electroplated-Pt mesh was pressed in the last layer, or for the special case of the circular cells used in the sealed configuration (see below) no current collector was used at that stage. Au was used in order to prevent CH₄ reaction with Pt, as carbon deposition was observed on bare Pt meshes which led ultimately to their complete disintegration. On the opposite side of the electrolyte, a three layered 1 cm² (square tapes) or 0.38 cm² (circular tapes) stoichiometric lanthanum strontium manganite (LSM, La_(0.85)Sr_(0.15)MnO₃) was symmetrically deposited with a Pt mesh current collector, or in the case of a symmetrical cell (see below and FIG. 1c), the same anode is applied with an Au electroplated Pt mesh. The cell thus obtained was then sintered under load (thermocompression) between 2 alumina cloths. A heating ramp of 90° C./h from room temperature to 600° C. was used in order to burn the organics, followed by a ramp of 180° C./h until the desired temperature indicated in Table 1. The cell was then kept at this temperature for 4 h and left to cool down to room temperature. Subsequently, a 5 mm×3 mm Pt electrode was pasted nearby (3 mm distance) the cathode as reference electrode, and in the special case of the circular cells used in the sealed configuration, a porous Au-LC paste was brushed on the anode, then sintered at 950° C. for 1 h with a heating ramp of 180° C./h. A schematic view of the different cells is given in FIG. 1.

[0067] The parameters addressed in this study are the lanthanum chromite composition, the presence of an adhesion layer made of LC+8YSZ composite between the YSZ electrolyte and the anode, the sintering temperature and the number of anode layers. The fact of using Pt meshes on the anode side, with their known activity toward CH₄, does not prevent to compare the different electrodes, as the preparation conditions are similar. Also, Au electroplating should prevent Pt from reacting heavily with CH₄.

[0068] Electrochemical Testing

[0069] a. Non-Sealed Configuration

[0070] The square cells (type a, FIG. 1) were mounted between inconel flanges with porous alumina felts on each side as electrical insulators and gas diffusers. This configuration was not sealed so that the excess fuel burned at the periphery of the cell. The tests were conducted in a Lenton EF 11/8 furnace. The gas inputs—air on the cathode side and fuel on the anode side—were controlled by rotameters, and the fuel line was heated in order to prevent water condensation. A valve allowed to switch between humidified H₂ or CH₄ to dry CO/CO₂ mixtures. Typically, air flow rate was of 300 ml/min whereas the fuel flow rate was set to 200 ml/min for H₂ and 70 ml/min for CH₄. Electrical contacts to the cell were made using silver wires welded to the Pt current collectors and taken to the outside of the oven through mullite tubes. The whole system was protected from electrical noise by a faradaic cage connected to the ground. A schematic view of the set-up is shown in FIG. 2.

[0071] Thus mounted, the cells were heated to 840° C. in 4 h under H₂+3% H₂O on the fuel side and air on the cathode side. The flange temperature was monitored by a K-type thermocouple pressed on its base, whereas the cells' temperature was followed by one S-type (Pt/Pt 10% Rh) thermocouple inserted beneath the anode and protected by an alumina wool. The electrochemical characterisations were performed in most cases starting from 840° C. in H₂ followed by a 1 night polarisation at 400 mV in order to activate the electrodes, specially the LSM cathode. The temperature was then raised to 900° C. and ultimately the gas was switched to CH₄+3% H₂O.

[0072] b. Sealed Configuration

[0073] The circular cells (type b, FIG. 1) were mounted over a machined Macor ceramic tube using an Au ring and self-made soda glass as sealing, with the anode set on the inside. The soda glass proved to be the most suitable among various commercial glass seals. The anode was then pressed to an Au mesh-current collector mounted on a Macor machined gas diffuser, and the whole cell was tightened using a machined Stumatite ceramic pressed on the cathode. This tightening allowed a better current collection and a higher stability of the seal. The electrical wires were passed through ceramic tubes protected by a metallic tubing or coating serving as faradaic cages. The cell was then mounted in a vertical oven (Horst, Germany) and heated to 860° C. in 4 h under Ar for the anode and air for the cathode, in order to melt the glass seal properly. The fuel gas was introduced just below the anode and extracted by a thin alumina tube at the bottom. Ounce at the desired temperature, the fuel gas was switched to wet H₂ and the cell OCV monitored to check the seal tightness. The anode gas flow rates were set to 30 ml/min, whereas the cathode air flow rate was of 150 ml/min. The anode gases were all monitored by mass flow controllers, and humidified in an oil thermostated bubbler. The cell temperature was monitored by a K-type thermocouple placed at the cell height, and occasionally by an S-type thermocouple pressed on the cathode side of the cell. A schematic view is given in FIG. 3. The outlet gases (O₂, N₂, Ar, CH₄, H₂, CO, CO₂ and eventually C₂s) were analysed by gas chromatography through syringe injection (Carlo Erba MFC500 and Gowmac instruments) and by a quadrupole mass spectrometer (Residual Gas Analyser, Spectra, Leda Mass Vision, HF-100, maximum mass of 100 a.m.u.). A Porapak Q column with He as carrier was used for Ar, CH₄, CO₂ and C₂-compound analysis (Carlo Erba) whereas a Molecular Sieve 5 Å with Ar carrier (Gowmac) was used for H₂, O₂, N₂, CH₄ and CO detection.

[0074] c. Symmetrical Configuration

[0075] The circular cells (type c, FIG. 1) were mounted in a horizontal quartz tube and electrical oven (Horst, Germany) and the electrical contacts to the cell were made using Au wires welded to the Au electroplated Pt current collectors (FIG. 4). A K-type thermocouple, protected in a quartz tube was placed in near the cell and served to monitor its temperature.

[0076] Humidified H₂ and CH₄ were used in all set-ups in order to prevent excessively reducing conditions which might decompose the electrodes ^(28, 32). At all stages, current/potential (INV) curves were performed on cells of type a and b with a Wenking potentiostat and impedance spectroscopy was conducted with an applied amplitude of 10 mV using a modified IM5 Zahner impedance analyser on all cell types. The frequency ranged from 100 kHz to 40 mHz. After the measurements, the pellets' cross-sections were imaged by a Philips secondary electron microscope (SEM). Some EDAX analysis were also performed in order to identify the interfacial composition between YSZ and the LCs as well as to estimate the composites layer thickness.

[0077] Conductivity Measurements and Relaxation Experiments

[0078] LC rods of 13×6×5 mm³ were pressed at 100 MPa and sintered at 1500° C. for 4 h. The pellets thus obtained were polished to the μm scale. DC four probe conductivity measurements were carried out in the same set-up as for the symmetrical configuration, in air and humidified hydrogen, using Ag paste and Ag leads as current and potential lines. The oxygen partial pressure was monitored by a home-built YSZ sensor placed near the sample.

[0079] Transient measurements were also performed in another quartz tube specially designed with a small gas volume to allow for rapid gas change. For this purpose, thinner rods (≈500 μm) were used. This kind of measurement was done in order to estimate the surface exchange coefficient and the oxygen diffusion coefficient, in order to investigate the possibility of surface exchange limitations in the electrode reactions.

[0080] Before and after polishing the rods, as well as after the conductivity tests, SEM micrographs (XLF30, Philips) were made to evaluate the surface composition of the samples.

[0081] Conductivity

[0082] Sintered pellet densities of the different lanthanum chromites varied with the nature of the incorporated element, the substitution of Cr giving rise to a better densification ^(17, 30). Compared to the XRD calculated density, unsubstituted LaCrO₃ gave low density pellets (63%), whereas the incorporation of Mn, Ni, Co and Mg increased the density to about 97, 95, 94 and 90% respectively. Ca and Sr had less effect in this regard, 71 and 67% respectively. A double substitution on the A-side with Ca or Sr and the B-side with Mg or Ni showed an enhanced effect on densification—97, 98 and 98.5% respectively for LSrCMg, LCaCNi and LCaCMg. Thus, it is seen that upon the incorporation of elements such as Mg, Mn, Co and Ni, all B-site substituents, the density is enhanced. This effect could be related to the lowered activity of Cr and thus the lowered CrOx species volatility which are responsible for the bad sintering of LC-based compounds ¹⁷. Some of these results are summarised in Table 2.

[0083] By introducing elements such as Ca, Sr and the transition metals on the La and Cr sites in LaCrO₃, the substitution on the A or B-site being depend on the ionic radius of the element, electronic compensation occurs by the formation of holes at high oxygen partial pressure, i.e. the oxidation of Cr^(III) to Cr^(IV), or of oxygen vacancies at low pO2 ³⁴. TABLE 2 Summary of the initial electrolyte and polarisation resistances at OCV, Re and Rp respectively, given in units of Ω · cm². Cell Sintering H₂ 840° C. H₂ 900° C. CH₄840° C. CH₄900° C. 800° C. 800° C. Anode composition Nr temperature [° C.] R_(e) R_(n) R_(e) R_(n) R_(e) R_(n) R_(e) R_(n) σ air σ H₂ La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2c 1200 1 15 1.1 7.9 0.7 34 0.9 25 14.8 1.9 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2d 1100 1 2.5 1.2 2.6 — — 0.8 6.2 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2f 1050 0.7 0.4 0.9 0.7 0.7 4 0.8 3.6 overnight 0.86 0.9 0.8 0.9 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E7b¹ 1100 0.32 0.16 0.27 0.11 0.29 — 0.26 — La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2b 1200 1.07 4.6 1.17 2.8 1 6.8 0.9 5 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2e 1100 1 1.4 1 0.5 0.54 0.5 2.8 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2g 1050 1.8 1.6 1.6 0.9 1 5.1 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E5h 1100 2.7 1.8 2.2 1.4 1.1 4 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E7c 1100 La_(0.85)Sr_(0.15)CrO₃ E5b 1100 2.6 0.9 La_(0.85)Sr_(0.15)CrO₃ E5a 1100 0.5 1 0.5 0.5 0.6 2.4 0.4 2.1 LaCrO₃ E5f 1100 9.6 13 8.8 5.6 7.1 23 8.8 13 0.4 0.05 LaCr_(0.9)Co_(0.1)O₃ E5i 1100 1.6 7 1.4 3.4 1.4 19 1.4 9.9 5.8 0.6 LaCr_(0.9)Ni_(0.1)O₃ E5e 1100 3.9 5.1 2.7 3.3 5 24 2 9 5.4 0.4 LaCr_(0.9)Mg_(0.1)O₃ B41 1100 5.1 0.16 La_(0.85)Ca_(0.15)Cr_(0.9)Mg_(0.1)O₃ B20 1100 9.7 0.3 La_(0.85)Ca_(0.15)Cr_(0.9)Mg_(0.1)O₃ B29 1100 0.5² 19.5 after polarization 0.37 2.3 0.7 La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ B21 1100 0.4³ 21.5 14.7 1.3 after polarization 0.37 1.7 0.85 6.1 La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ B24 1100 0.4 32 0.4 35 La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ B30 1100 17.6 9.1 La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ B37 1050 La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ E5d 1100 1.2 1.3 1.4 1.6 1 6 1.1 6.2

[0084] The conductivities, σ, in air and in humidified H₂ (3% H₂O), are given in units of S/cm. It is to be noted that the conductivities of La_(0.85)Ca_(0.15)Cr_(0.9)Ni_(0.1)O₃ and La_(0.85)Sr_(0.15)CrO₃ are those of the Ca substituted compounds, as these values were not measured for the Sr substitution. ¹: cell temperature of 864° C. and 874° C. instead of 840° C. and 900° C.; ² 828° C.; ³ 800° C. Bold numbers correspond to measurements made after the cell degradation.

[0085] Due to the differences in rod densities, all conductivity measurements were normalised for a 100% pellets density by using the approximation

d _(eff) /d _(theo)=σ_(eff)/σ_(theo)  (3)

[0086] where deff and σeff are the measured density and conductivity respectively and dtheo and σtheo the theoretical density (XRD) and conductivity respectively. The conductivity trend observed are comparable to values extrapolated from literature data ³⁴ and it followed the concentration of Cr^(IV). Ca or Sr substitution gave rise to a higher conductivity in air and in humidified H₂ than the B site substituents.

[0087] Effect of the Sintering Temperature

[0088] Prior to the electrochemical tests, half cells were made by screen-printing La_(0.85)Ca_(0.15 Cr) _(0.9)Mg_(0.1)O₃, La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ and La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ slurries on YSZ pellets. For these compositions, different sintering temperatures were investigated (1000-1300° C.). Subsequently, these half cells were treated in H₂+3% H₂O at 800° C. for some hours. After cooling to room temperature, the adherence and the morphology of the electrodes were verified by abrasion tests (using a cutter) and in some cases by SEM imaging. Firing at 1100° C. was optimal, whereas lower temperatures gave poor adherence while firing at 1200° C. produced some surface reaction with YSZ ²⁹.

[0089] The effect of the sintering temperature was also studied in more details with the two systems, La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ and 55.7:44.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃:8YSZ, by electrochemical means. I/V curves and impedance spectroscopy analysis were performed with H₂+3% H₂O or CH₄+3% H₂O as fuel, at two temperatures, 840° C. and 900° C., with unsealed cells sintered at 1050° C., 1100° C. and 1200° C. I/V curves and power outputs, as well as anode overpotentials (ηa) values are given in FIGS. 5 to 8.

[0090] In the case of La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃, the current output was higher and the overpotential lower, in both humidified H₂ and CH₄, when the cell was sintered at 1050° C.>1100° C.>1200° C. (FIG. 5,6). The maximum power output reached at 900° C. in humidified H₂ at the sintering temperature of 1050° C. was of 250 mW/cm² with a short circuit current of almost 1200 mA/cm². However, the cell performance was only stable when sintered at 1200° C. For the 1100° C. and 1050° C. sintering, the performance degraded rapidly with time as observed by impedance spectroscopy. The anodic polarisation resistance values, Rp, for the cell sintered at 1050° C. increased by 2.25 times overnight, while the anodic electrolyte resistance, Re, changed by a factor of 1.2, resulting in the rapid degradation of the current output (Table 2). Also, the Rps were significantly higher with increasing sintering temperatures, increasing 37 and 11 times in humidified H₂ at 840° C. and 900° C. respectively, and 7 times in humidified CH₄ at 900° C., between cells sintered at 1050° C. and 1200° C. SEM micrographs show densification of the anode structure the higher the sintering temperature (FIG. 9). The mean anode grain size was of 1 μm at 1200° C. whereas it was in the submicron scale at lower sintering temperatures. From the micrographs, the structure seemed to be more loose at 1050° C. as after the test some delamination was observed. SEM-EDAX analysis made on the 1200° C. sintered anode showed a topotactic reaction between the La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ electrode and the YSZ, most probably due to SrZrO₃ formation (FIG. 11).

[0091] For 55.7:44.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃:8YSZ, the current output is higher and the overpotential lower when the cell was sintered at 1100° C.<1050° C.<1200° C., in both humidified H₂ and CH₄ (FIG. 7,8). The maximum power output reached at 900° C. at the sintering temperature of 1100° C. was of 140 mW/cm² with a short circuit current of more than 600 mA/cm² in humidified H₂ and 500 mW/cm² in humidified CH₄. It is interesting to see that the power outputs in humidified H₂ and CH₄ are of the same amplitudes. The cell performances were stable for the cases of 1200° C. and 1100° C. over a period of more than 1 day. For the sintering temperature of 1050° C., the stability was less pronounced, and this was most probably due to delamination as observed post-mortem by SEM. YSZ composites seem to sinter badly at 1050° C. As for the case of La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ anodes, the higher the sintering temperature the denser the electrodes (FIG. 10). The mean thickness of the adhesion composite layer was estimated by line-scan EDAX analysis to be of approximately 5 μm. The Re and Rp followed a similar trend with sintering temperature, i.e., 1100° C.<1050° C.<1200° C. (Table 2). The Rp was lowered by a factor of 3 and 5.6 in humidified H₂ at 840° C. and 900° C. respectively, and 1.8 in humidified CH₄ at 900° C., between 1200° C. and 1100° C.

[0092] It is thus observed that in both cases, the Re was higher than the expected value for YSZ electrolyte. For a 150 μm thick Kerafol 8YSZ plate, the electrolyte ohmic loss is expected to be of 0.38 and 0.27 Ωcm² at 840° C. and 900° C. respectively. Also, in both La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ and 55.7:44.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃:8YSZ anodes, the sintering temperature of 1100° C. was optimal. This temperature was adopted hereafter. The application of an adhesive layer also seemed to increase the stability of the system, as in the absence of the layer delamination was observe to occur rapidly.

[0093] Effect of Polarisation on the Cell Performance

[0094] The impedance analysis of two set of anodes, a LaCaCrMg (B29) and a LaSrCrMg (B21), sintered at 1100° C., show clearly the influence of polarisation on the anode formation (Table 2). Prior to the passage of current, the polarisation resistance, Rp, measured in humidified H₂ at 850° C., were of 19.5 and 21.5 Ωcm², for the first and the second electrode respectively. After one night polarisation, these resistances dropped to 2.3 and 1.7 Ωcm² respectively, by a factor of approximately 10 (see FIG. 12). The summit frequencies tended to increase after polarisation. The drop in the polarisation resistance occurred in general after 1 h of polarisation. This phenomena is similar to that observed on LSM electrodes ³⁵.

[0095] Also, upon current withdrawal, the impedance showed an activated process, as the total Rp dropped by a factor of 2 between OCV and 400 mV in humidified H₂ (FIG. 13). This correlates well with the overpotential-current evolution (FIG. 14) where a net activation process is observed upon polarisation. The impedance responses were best fitted by a three arcs LRe(R1Y1)(R2Y2)(R3Y3) circuit, using the Zahner fitting software. Yi is a constant phase element (CPE) ³⁶.

Y _(i) =Y _(i,O)(jω)^(n)  (4)

[0096] with Y_(i,o) an admittance factor, j the imaginary unit, ω the angular frequency (2πf, f being the frequency), n the frequency power, Re the series electrolyte resistance between the reference electrode and the working electrode, Ri a resistance, and L the current/potential collectors inductance. One physical interpretation of Y_(i,o) is as a distributed capacitance, as when n=1, this value turns to be a capacitance, C. The inductance was added in this manner after trials made with ceramic resistors and capacitors, which were best interpreted by taking into account the current and potential leads, which are primarily responsible of L. L was constant, with some variation measurements. This simple equivalent circuit was chosen as no knowledge of the reaction mechanism was available. This approach condenses however the data and allows for their interpretation. The general values for n₁, n₂, n₃ and L were 0.76-0.9, 0.8-1, 0.85-0.9, and 643 nH, and the mean fitting error was of 0.1-0.4%, whereas the maximum error was of 1-4%.

[0097] When the anode was polarised, the series ohmic resistance tended to decrease (FIG. 15). Between OCV and 400 mV, the current density rose to about 350 mV/cm², and the Re was lowered by about 15%. This might be due to the increase of the anodic oxygen potential which would lead to an increase of the overall electronic conductivity of the electrode, as the electronic conductivity of the lanthanum chromites is of the p-type. For the LSrCMg, the conductivity in air was of: 15 S/cm whereas it dropped to only 1.3 S/cm in humidified hydrogen (Table 2).

[0098] The evolution of R₁—C₁, R₂—C₂ and R₃—C₃ with the anodic overpotential is shown in FIG. 16. R₁ and R₂ decreased while R₃ increased with the overpotential. C₁, C₂ and C₃ also decreased with the polarisation. Average summit frequencies, given as $\begin{matrix} {{{f_{i}\quad\lbrack{Hz}\rbrack} = \frac{1}{2\quad \pi \quad R_{i}C_{i}}},} & (5) \end{matrix}$

[0099] were of 10 kHz, 4 kHz and 23 Hz for the first, second and third arc respectively. Upon aging, all the R values increased, as well as C₁ and C₂, C₃ being almost unchanged (FIG. 17). This is due as previously discussed to the absence of the adhesive composite layer. The power output was observed consequently to decrease (FIG. 16). Eventually, the degradation ceased and a stable value was reached (FIG. 16). The evolution of R₃ and C₃ with the H₂O partial pressure (FIG. 18), R₃ decreasing and C₃ slightly increasing, could be a hint of a gas conversion impedance ³⁷. Moreover, this fact was confirmed by the absence of this third arc when a symmetrical cell configuration was used (see FIG. 19).

[0100] Effect of H₂, CH₄, H₂O, CO/CO₂ on LC Polarisation

[0101] The theoretical OCVs in the gas phase versus air were calculated using the HSC-4.1 gas phase thermodynamic equilibria calculation software. In H₂+3% H₂O an estimate of −1139 mV at 850° C. and −1035 mV at 900° C. were obtained, while in CH₄+3%.H₂O the values rose to −1260 mV at 850° C. and −1290 mV at 900° C. The experimental OCV in hydrogen was typically of −1000˜1030 mV (see for example FIGS. 5 and 7), an acceptable value in view of the open configuration of the testing set-up. In methane, the value was quite high, around −1200 mV (see for example FIGS. 5 and 7). These values were typical for all tests made in the unsealed configuration. The OCV in CH₄ was however higher than the expected OCVs calculated from previous catalytic measurements ³¹. Measurements done in the sealed configuration with LCaCMg and LSrCMg electrodes gave on the contrary OCVs matching well these predicted values in CH₄ ³¹. The measured OCV for LSrCMg was of 862 mV (FIG. 20), matching well the previous estimate of 880 mV, based on the catalytic study. The low potential is not due to air leakage to the anode chamber, as the OCV in wet hydrogen was of −1089 mV, a value which did not change after contacting the anode with CH₄ (i.e., the process is reversible). Also, in this configuration, OCV measurements made as a function of the steam to carbon ration (S/C) (FIG. 20a) and MS gas analysis of the anode gas exhaust (FIG. 20b) in the case of LSrCMg indicated that the oxygen partial pressure was determined primarily by the PH₂O/PH₂ equilibrium from the H₂ +½O ₂=H₂O reaction. The S/H ration was of 3.43.9, while the ratio of CO₂/CO was of 0.6.

[0102] By considering the following reactions

CH₄→C+2H₂; irreversible  (6)

and

H₂O═H₂+O⁻  (7)

C+O⁻═CO  (8)

C+H₂O═CO+H₂  (9)

and

CO+H₂O═CO₂+H₂; gas shift reaction  (10)

C+2H₂O═CO₂+2H₂; Kp(850° C.)=12.94  (11)

[0103] where equation (7) and (8) can be considered the contraction of

½O₂+2e ⁻═O⁻⁻  (12)

with H₂O═H₂+½O₂  (13)

or C+½O₂═CO  (14)

[0104] and considering CH₄ as an inert gas (e.g. Ar) then using the measured exhaust gas composition (H₂, H₂O, CO and CO₂), the HSC-4.1 gave an OCV between 858 and 865 mV (FIG. 20), also in agreement with the other values. From these calculations, the carbon activity was estimated to ˜10-5, indicating no carbon deposition. Also, the estimated CH₄ conversion was of 0.3% in good agreement with the catalytic steam-reforming tests (0.22%). LCaCMg anodes performed equivalently (FIG. 21). The situation was similar for Au anodes (inset FIG. 20a), where an OCV of ≈700 mV was slowly attained in humidified CH₄. Non-ideal electromotive forces were also observed in literature on Au electrodes deposited over zirconia for sensors with hydrocarbon gases and O₂ ^(38, 39). This mixed potential that developed, being dependent on kinetic factors, is expected to be a strong function of the electrode material. Thus, the discrepancy between the expected and actual OCV in the open set-up could be related to some methane pyrolysis over the metallic flange, rather than coking over the LC perovskites as no carbon build up was observed by temperature programmed analysis (TPO) in catalytic runs in humidified CH₄ over the same catalysts ³¹. Dry hydrogen is then expected to reach the anodes after the pyrolysis. Nevertheless, all test made in methane gave the same OCVs, independently of the anode composition, so that this effect is not expected to have any effect when comparing the different substitutents.

[0105] The performance of LC anodes in humidified H₂, CH₄ and dry CO/CO₂ fuels is depicted in FIGS. 14 and 22, in the case of the LSrCMg system. The power output increases and the overpotential decreases in the order of CO—CH₄—H₂. The Rp changed at 850° C. from 9.2 to 6.1 to 1.7 Ωcm₂ from CO to CH₄ to H₂. This indicates that the electrochemical oxidation rate of H₂ was higher than for CH₄ which was in turn higher than for CO. Increasing the CO₂/CO ratio reduced further more the cell performance (FIG. 23), with the Rp increasing to 17.2 Ωcm²—the OCV passed from 1003 to 882 mV, as expected. This could eventually indicate some inhibiting effect of CO₂, as observed earlier ³¹. The inhibition could be related to the surface segregation of Ca or Sr on these materials, as these elements are basic sites capable of interacting with CO₂ to form carbonates. The latter, could block the catalytically active sites for oxidation. Such inhibition was reported on La₂O₃ catalysts ⁴⁰ and interpreted as the interaction of CO₂ with active oxide species responsible for methane and oxygen activation. Moreover, CO₂ reforming was observed to be quite low with the basic LC compounds ³¹.

[0106] The impedance spectra obtained for humidified H₂ and CH₄ have similar appearances, as shown for the case of a symmetrical LSrCMg cell in FIG. 19. In this case two arcs were observed with summit frequencies of about 4.5 kHz and 45 Hz in H₂ and 4 kHz and 18 Hz in CH₄ at 850° C. These frequencies are somewhat lower in methane. The second arc seemed the most sensitive to the gas atmosphere, as R₁ and C₁ were similar in both humidified H₂ and CH₄, while R₂ was about 5.6 times higher in CH₄ (2.5 Ωcm² in H₂ and 14 Ωcm² in CH₄) respectively, while C₂ was 2.6 time less in CH₄, 702 μF in H₂ and 275 μF in CH₄. Water was previously observed to have almost no effect on the catalytic activity of LSrCMg and LCaCMg. In the electrochemical experiment of FIG. 20, water modified the OCV values as the H₂O/H₂ ratio was changed at higher humidity values. Also, the higher the working temperature, the better the cell performance, with a temperature limit of about 850° C., below which the performance is poor, in both H₂ and CH₄ (FIG. 24). The effect of water on the polarisation losses were almost negligible (see FIG. 18 for H₂ and 25 for CH₄). In methane, the effect of water was only observed at high current densities (FIG. 25). This goes in parallel with the previous report ³¹ of the poor steam reforming ability of the basic LC oxides in catalytic mode.

[0107] Effect of the Substituent on the Performance of LC Anodes

[0108] 4 different lanthanum chromite anodes were considered for the analysis of the substitution effect: LaCrO₃ as base material, La_(0.85)Sr_(0.15)CrO₃, LaCr_(0.9)Co_(0.1)O₃ and LaCr_(0.9)Ni_(0.1)O₃. These electrodes were made of 1 composite ≈56:44 LC:YSZ layer, and 3 layers of the LC, and were sintered at the optimal temperature of 1100° C. As discussed before, this structure allowed a higher stability and a better adhesion of the electrode. The composite layer thickness was estimated by SEM-EDAX analysis to 5 μm in all cases. The electrodes morphology observed were quite similar, showing the fine composite layer, and the coarser LC layer (FIG. 26). The electrode grains followed roughly the initial particle size distribution of the starting LC powders, i.e., d50 of 0.8 μm, 1.0 μm, 2.1 μm and 2.1 μm for LaCrO₃, La_(0.85)Sr_(0.15)CrO₃, LaCr_(0.9)Co_(0.1)O₃ and LaCr_(0.9)Ni_(0.1)O₃. All these electrodes stuck quite well on the YSZ electrolyte substrate, even after electrochemical testing. These tests were made in the unsealed configuration set-up.

[0109] The potential-current and power curves were affected by the substituent in LaCrO₃ (FIG. 27). Globally, upon Sr, Co or Ni substitution, the LaCrO₃ base material activity increased both in humidified hydrogen and methane. The Re and Rp were lowered significantly in the trend LC>LCCo>LCNi>LSrC. The Re was lowered by a factor of 19 at 840° C. and 17.6 at 900° C. in humidified H₂, and 11.8 at 840° C. and 22 at 900° C. in humidified CH₄ (Table 2). For the Rp, the factor was of 13 at 840° C. and 11 at 900° C. in humidified H₂, and 9.6 at 840° C. and 6.2 at 900° C. in humidified CH₄ from LC to LSrC (Table 2). The evolution of the Re, corrected from the expected ohmic loss of half of a 150 μm thick Kerafol 8YSZ electrolyte, as a function of the electric conductivity of the different LCs, was linear in both temperature ranges (FIG. 28). The similar trend was observed with the Rp. The higher the electronic conductivity, the lower the Rp. This indicates clearly that the electronic conductivity has an influence on the global performance of these anodes.

[0110] The substitution effect on the LaCrO₃ electrode performance is better depicted by the overpotential curves in FIG. 29. The overpotential losses trend was LC=LCCo>LCNi>LSrC>LSrCNi in humidified H₂ at 840° C. and 900° C. and humidified CH₄ at 840° C., and LC>LCCo>LCNi>>LSrC>LSrCNi in CH₄ at 900° C. The overpotential losses of LC and LCCo laid very near together even though the electronic conductivity of LCCo was 6 times higher than for LC. This indicates that the substituent plays also an important role in the electrocatalytic activity. Previously, the catalytic activity of these different oxides were assessed in methane rich gas mixtures (5:1 CH₄:O2, 5:1:0.6 CH₄:O₂:CO₂ and 56:x:y CH₄:Ar:H₂O (x+y=44)) 31. It was observed that the activity, expressed as a turn-over frequency (TOF), followed the order of LC=LCCo<LSrC<LCNi<LSrCNi at 850° C. in wet CH₄. A direct relationship between the electronic and catalytic activity and the electrocatalytic performance is thus evidenced here.

[0111] Ni substitution is further observed to enhance the performance of the cell in methane. By addition of Ni on the Cr site, the LSrC performance in CH₄ increased markedly (compare FIGS. 7 and 30). Whereas the short circuit current was of 650 mA/cm² in humidified H₂ and 350 mA/cm² in humidified CH₄ over a LSrC anode, it was of 620 mA/cm² in H₂ whereas of 520 mA/cm² in CH₄ over LSrCNi at 900° C. Methane is thus better activated over the Ni substituted compounds. In this case, the power outputs were similar in hydrogen and methane.

[0112] A trial has been made to further increase the activity of LSrCNi anode by adding one more layer made of LaCr_(0.85)Ni_(0.15)O₃. No effect of this layer was observed in hydrogen nor methane (Table 2).

[0113] Also, the difference between A-site substituents, Ca and Sr, lies in the difference in Rp, with a lower value for Sr substitution (2.3 Ωcm² for Ca versus 1.7 Ωcm² for Ca, Table 2). Beside that, thermodynamic calculations showed the higher stability of the Sr versus Ca-substituted LC and the increasing solubility of Sr in reducing atmospheres ³¹. However, the sintering process of Ca versus Sr incorporated in LC is known to be more favourable due to the lower melting temperature of CaCrO₄ or the like (1000-1020-1120° C. 12, 41) than for SrCrO₄ (1253° C. 12, 42). If secondary phases are left behind during the powder preparation and the anode sintering, these phases would then react readily with YSZ to form SrZrO₃ ³¹. B-site substituted LC are expected to be more stable, as their demixing seemed to be hindered kinetically ^(32, 43).

[0114] Effect of the Composite Layer Composition on the Performance of LC Anodes

[0115] 44% YSZ composite anodes showed by electrochemical analysis to be more stable over time than the ones without YSZ (0%) as exposed in the case of LSrCNi (compare FIGS. 5-6 and 7-8). This was also observed for the LSrC anodes. However, the initial performance of these LSrC and LSrCNi anodes were higher in the non-composite form. Indeed, lower Rp and Re were observed (Table 2), giving rise to a higher power output. These values degraded however very rapidly by a factor of 2.25 and 1.2 respectively. This loss in performance was predominantly due to delamination. Further, LC lacking A-site substitution (Ca or Sr) were very sensitive to delamination and their power output was hence reduced (e.g., FIG. 31 for LCMg).

[0116] The two extremes used in the composite anodes were 0% YSZ and 44% YSZ. A 22% YSZ composite anode, the lower limit allowed for a percolating structure ⁴⁴, was also investigated in the case of the LSrCNi anode. FIG. 32 shows the potential-current and the power output of the cell in humidified H₂ or CH₄ at different temperatures. The short circuit current and the power output were increased by a factor of 1.43 in CH₄, and by 4.44 in H₂ at 840° C., when compared with the 44% YSZ composite anode. As a result of a high current density, the passage of current induced a local increase of the anode temperature (FIG. 33a) as measured by the thermocouple placed beneath the electrode (see FIG. 2).

[0117] In this system, the ohmic resistances are lowered significantly, by a factor of 3. However theses losses are still higher than the expected losses for a 150 μm 8YSZ Kerafol (e.g., 0.38 Ωcm² at 850° C.). The temperature dependence of these losses is given in FIG. 33b. An activation energy of 55±5 kJ/mol was measured, a value lower than the expected 77 kJ/mol for 8YSZ Kerafol plates, showing still the effect of the electrode conductivity on R_(e). On the other hand, the anode overpotentials were significantly lowered (FIG. 34) compared to the 0% and 44 YSZ extremes (FIGS. 6 and 8). This cell configuration sustained CH₄ at 877° C. for 136 h, almost without degradation (a small degradation was observed in the first 24 h). The addition of 22% YSZ appears to favour the performance of the anode.

[0118] Effect of the Anode Thickness on the Overall Performance

[0119] The anode thickness deposited above the composite electrode was reduced from 3 to 1 layer. The anode performance showed to increase as exposed in FIG. 35 when compared to the case of 3 layers (FIG. 7). However, the long term stability was poor. The time degradation of R_(e), was lower than that of R_(p), indicating that a small degradation of R_(e) modifies R_(p) drastically.

[0120] Nature of the Electrode Reaction

[0121] The sintering temperature and the incorporated elements were shown to have an effect on the anodic electrolyte resistance. An optimum temperature of 1100° C. was necessary to stick efficiently the electrode on the YSZ electrolyte and to prevent the formation of a topotactic reaction leading to SrZrO₃. Sintering at a lower temperature lead to the delamination of the electrode. A better stability was further obtained by adding an adhesion layer in between the LC anode and YSZ. The series resistance was thus observed to be very sensitive to the nature of the interface (about 1 Ωcm² for the 0% and 44% YSZ composite adhesive layer and 0.32 Ωcm² for the 22% YSZ composite adhesive layer (see Table 2)). An additional ohmic loss was also stemming from the low conductivities of these perovskites From the measured electronic conductivity in reducing conditions a 200 mΩcm², 25 mΩcm², 16 mΩcm² and 11 m(cm² losses are expected for dense LC, LCNi, LCCo and LSrC electrodes of 100 μm thickness and 1 cm² surface respectively. Due to the porosity of the working electrodes, an ohmic loss higher by a factor of at least 10 could be expected ⁴⁵ (i.e. 2000, 250, 160 and 110 mΩcm²). TABLE 3 Summary of the R_(p) activation energies. Cell Sintering R_(p) E_(a) [kJ/mol] R_(p) E_(a) [kJ/mol] E_(a) [kJ/mol] E_(a) [kJ/mol] E_(a) [kJ/mol] Anode composition Nr temperature [° C.] H₂ + 3% H₂O CH₄ + 3% H₂O σ_(o)− σ_(e,) air σ_(e,) H₂ La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2c 1200 116 87 9.7 32.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2d 1100 87 9.7 32.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2f 1050 19 87 9.7 32.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E7b 1100  406? 87 9.7 32.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2b 1200  87 56 87 9.7 32.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2e 1100 186 87 9.7 32.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E2g 1050 104 87 9.7 32.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E5h 1100  49? 87 9.7 32.3 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ E7c 1100 87 9.7 32.3 La_(0.85)Sr_(0.15)CrO₃ E5b 1100 87 5.2 5.4 La_(0.85)Sr_(0.15)CrO₃ E5a 1100 125 24 87 5.2 5.4 LaCrO₃ E5f 1100 152 103 87 6.4 34.9 LaCr_(0.9)Co_(0.1)O₃ E5i 1100 131 118 87 20.1 29.9 LaCr_(0.9)Ni_(0.1)O₃ E5e 1100  79 177 87 7.3 16.6 La_(0.85)Sr_(0.15)Cr_(0.9)Mg_(0.1)O₃ E5d 1100 87 6.6 6.5

[0122] The conductivity E_(a) for LSrC and LSrCNi were taken to be those of LCaC and LCaCNi. σ_(O) ²⁻ is taken from reference ⁴⁶.

[0123] The effect of the substituent on the R_(p) losses were also significant. This implies that the conductivity played also a role in the electrode reactions. This is in contradiction with the result of Primdahl et al. who argued that conductivity should not have any influence on their La_(0.8)Sr_(0.2)Cr_(0.97)V_(0.03)O₃ electrode ²⁷. Apparent activation energies for the different R_(p)s are summarised in Table 3. These values vary in general between 80 and 190 kJ/mol. As for the electronic conductivity, it had a higher activation energy in H₂ than in air, with values varying between 5 and 20 kJ/mol in air and 5 and 32 kJ/mol in wet H₂, whereas the ionic conductivity varied, in the case of La_(1-x)Sr_(x)Cr_(1-y)Ni_(y)O₃, between 87 (x=0.2, y=0.05), 142 (x=20, y=0) ⁴⁷ and 93 ⁴⁷ or 137 ⁴⁶ kJ/mol (x=0.35, y=0) and 77 kJ/mol for La_(0.7)Ca_(0.3)CrO₃ ⁴⁷. Correspondingly, the activation energy for the ionic leak current density, which takes into account the variation of the vacancy concentration between two different gas atmospheres, is between 130 and 195 kJ/mol ⁴⁷. Beside that, conductivity transient measurements made on thin rods of LCaCNi and LCaCMg at 800° C., upon a rapid change of the gas atmosphere from air to wet H₂ (using Ar), indicated a slow exponential decrease in the conductivity with time (FIG. 36). The behaviour was reversible upon reoxidation giving rise to the same initial conductivity in air. A trial was made to analyse this behaviour using the concept of oxygen diffusion in the materials, taking into account the surface exchange and the diffusion coefficients. A rough estimation of the exchange coefficient, κ, taking a starting value for the vacancy difflusion coefficient of D_(v) _(o) ._(800° C.) of 1.2×10⁻⁶ cm²/s ^(46, 47) gave an approximate value of about 10⁻⁶ to 10⁻⁷ cm/s, which could indicate a surface limiting process for the reduction. Yasuda et al. ⁴⁶ presented a coefficient D_(v) _(o) ._(850° C.) of 2.9×10⁻⁸ cm²/s and κ of 1×10⁻⁴ cm/s using a similar technique. Taking the concept of Adler et al. ^(48, 49) depicting the length δ of the reaction zone on the electrode, $\begin{matrix} {\delta \approx \sqrt{\frac{\left( {1 - ɛ} \right)}{\tau}\frac{L_{c}}{a}}} & (15) \\ {{{with}\quad L_{c}} = \frac{D^{*}}{\kappa}} & (16) \\ {{{and}\quad D^{*}} = {f\quad D_{v_{o}^{\quad..}}\frac{c_{v}}{c_{mc}}}} & (17) \end{matrix}$

[0124] where ε the porosity (taken as 0.3), a the surface area (taken as 10000 cm²/cm³), τ the solid phase tortuosity (taken as 1), D* the tracer diffusion coefficient, f the correlation factor (taken as unity⁵⁰), c_(mc) the concentration of oxygen sites in the mixed conductor determined from the lattice parameter 1.9×10⁻² mol/cm³ for the LCs), and c_(v) the vacancy concentration (around 10⁻³ mol/m³ for the LCs), it could be possible to roughly estimate a reaction length of 2 to 4 μm inside the electrode structure. In air, the κ is around 10⁻⁴ cm/s. A more accurate evaluation of D_(v) _(o) . and κ could be obtained from more reliable data. Such a change in the exchange coefficient could explain the slow reduction process. This preliminary evaluation could also explain the slow degradation of the activity of the lanthanum chromites over a period of about 20 h observed during polarisation. Reoxidation of the material leads thus to a reversible activity. It also could give more insight on the mechanism of the reaction. It may be interesting to evaluate partial oxidation on the chromite (CH₄+O₂), O₂ possibly hindering the extreme reduction of the electrode. This along with the activation energies and the correlation with the electrode conductivity might indicate a surface chemical process limitation related to the perovskite surface.

[0125] Also, by Adler et al. ^(48, 49), a chemical impedance Z_(chem) was defined relating the D_(v) _(o) . and κ, as $\begin{matrix} {{R_{chem}\quad\left\lbrack {\Omega \cdot {cm}^{2}} \right\rbrack} = {\left( \frac{RT}{2F^{2}} \right)\sqrt{\frac{\tau}{\left( {1 - ɛ} \right)\quad c_{v}D_{v}a\quad \kappa \quad c_{mc}}}}} & (18) \\ {{C_{chem}\quad\lbrack F\rbrack} = \frac{2{F^{2}\left( {1 - ɛ} \right)}c_{v}\delta}{ART}} & (19) \\ {Z_{chem} = {R_{chem}\sqrt{\frac{1}{1 - {j\quad {w\left( {C_{chem}R_{chem}} \right)}}}}}} & (20) \\ {{{with}\quad A} = {\frac{1}{2}\frac{\partial{\ln \left( P_{O_{2}} \right)}}{\partial{\ln \left( c_{v} \right)}}}} & (21) \end{matrix}$

[0126] By taking into account the values of D_(v) _(o) . and κ of Yasuda et al. ⁴⁶ and our estimates for κ in humidified H₂, as well as an estimate of A obtained from nonstoichiometry studies of La_(0.9)Sr_(0.1)CrO_(3-δ) ⁵¹, the difference in behaviour between an unpolarised and a polarised electrode could be interpreted as a local change in the activity of the electrode related to its reduction and thus to the decrease of the surface exchange coefficient. By polarising the electrode, a partial reoxidation will occur leading to the increase in the surface exchange coefficient. This will lead to a decrease in the impedance polarisation resistance, R_(p). In Table 4, a trial was made to estimate and summarise this expected change. TABLE 4 Effect of the κ on a presumed chemical impedance Calculated Parameters values values air wet H₂ τ 1 δ [μm] 1.4 14.4 ε 0.3 D * [cm²/s] 2.96 × 10⁻⁸ 2.96 × 10⁻⁸ A 647.5 C_(chem) [F/cm²] 3.10 × 10⁻⁴ 3.10 × 10⁻³ a [cm²/cm³] 10000 R_(chem) [cm²]  0.18  1.83 κ_(air) [cm/s]   1 × 10⁻⁴ ƒ_(max) [Hz] 2799    28   κ_(H) ₂ [cm/s]   1 × 10⁻⁶ D_(v) _(o) ..[cm²/s] 5.62 × 10⁻⁷

[0127] To apply this on our system, an example of an unpolarised electrode is taken from the symmetrical cell analysis (B24), where two processes were observed by impedance spectroscopy, with activation energies of 139 kJ/mol and 122 kJ/mol in humidified H₂, and 95 kJ/mol and 24 kJ/mol in humidified CH₄ for R₁ and R₂ respectively (FIG. 37). The C₁ activation energy did not vary much with temperature and gases (FIG. 37), with a value of about 10 μF/cm² (see also FIG. 17). C₂ seemed to be less affected by the temperature with values of 630 to 250 μF/cm² in humidified H₂ and CH₄ respectively. Globally, by comparing with the results previously shown in FIG. 17 (B21), the second process (R₂—C₂) had a resistance of 5 cm² and a C of 794 μF/cm² (f_(max)=40 Hz) for the unpolarised cell (B24) versus 1.3 cm² and 100 μF/cm² (f_(max)=1224 Hz) for the polarised cell (B21), at 850° C. and in humidified H₂. This might indicate that the second process is related to the chemical impedance described by Adler et al. 4 Primdahl et al., on the basis of H₂/D₂ isotopic effect studies, suggested that this process might be related to H₂ adsorption or to a chemical reaction step ²⁷. Also, hydrogen adsorption on NiO and its oxygen vacancies is reported to be of 96.4 kJ/mol, whereas hydrogen diffusion over YSZ is reported to be of 119.5 to 159.9 kJ/mol ^(52, 53). These values are not far from the measured activation energies of both processes. However, the first process, (R₁—C₁), due to R₁'s lower sensitivity to the gas atmosphere and to equally low values of C₁ (10˜20 μF/cm²) in CH₄ and H₂ (FIG. 37) and to its potential independent behaviour (FIG. 17), at least before the cell's degradation in the case of B21, might be related to a chemical step or to charge transfer ^(54, 55). The summit frequency for the first process was of 5 kHz for the unpolarised and 10 kHz for the polarised one. In general, in both processes, the summit frequency tended to increase as the cell was polarised, showing an electrocatalyzed process.

[0128] In both processes, gas diffusion as well as gas conversion impedances could be ignored, as the summit frequencies of these kind of losses would range between 15 and 400 Hz. This was estimated for humidified H₂ and CH₄ on the basis of literature ^(37,56) by taking into account the testing configuration and the interdiffusion coefficient of H₂O in H₂ and H₂ in CH₄. Similarly, estimates for CO₂/CO fuels indicated negligible losses too.

[0129] The effect of the substituent on the polarisation of the cell cited above indicates furthermore that the catalytic effect has an important role in the electroactivity of these materials. In methane the activity follows the same trend as for the catalytic tests made in CH₄ rich atmospheres ³¹ (FIG. 29). Ni incorporation had also a positive effect in wet H₂ (FIG. 29). Thus total conductivity of the electrode material was an important factor in the performance but it was also tempered by the catalytic activity (ex. LCCo has a higher conductivity than Ni but a lower catalytic and electrocatalytic activity).

[0130] Also, as the OCVs of the LCs in wet CH₄ were governed by the H₂/H₂O equilibrium over the electrode, it could be reasonable to suggest that H₂ oxidation was masking the overall CH₄ electrooxidation process, at least under low current densities. This H₂ stems from the local steam-reforming of CH₄, with a CH₄ conversion of no more than 0.3%, in accordance with previous catalytic runs. From the MS gas analysis of sealed LCaCMg and LSrCMg cells, H₂ concentration was observed to be low, being of about 0.51% (FIGS. 20 and 21). Even though there were both CO and CO₂ in the gas surrounding the anode with a ratio of CO₂/CO 0.6, CO oxidation seemed not to affect the anode potential. As pointed out previously, the anode polarisation resistance under CO—CO₂ gas mixture was much higher than in CH₄ or H₂. The R_(p)s were of 1.7 in H₂, 6.1 in CH₄ and 9.2 to 17.2 cm² in CO₂/CO of 0.14 and 1.44. Thus the kinetics of CO oxidation are about 1.5 to 2.8 time lower than for CH₄, and 5.4 to 10.2 time lower than for H₂. The low OCV values did not reflect the direct oxidation of CH₄, but rather H₂ and in much lower proportion CO oxidation. This might be the reason for this OCV effect. Norby et al. ²⁴have shown that the presence of water prevented carbon deposition over a La_(0.7)Ca_(0.3)CrO₃ anode which lead in the case of dry CH₄ to very high OCVs of 1500 mV. This might indicate, that the electrode impedance in humidified CH₄ might be related to hydrogen rather than CO or C as C direct oxidation was observed to be very slow over metallic and oxide electrodes ^(3,25,57).

[0131] The MS analysis of the anode gas composition under current load shows that all methane consumed corresponds to the faradaic current. From the analysis, CO seemed to increase with current, and H₂ to decrease, when compared to OCV (i.e. catalytic reaction). It is not very clear whether the mean reaction is partial oxidation, with a concomitant oxidation of H₂, or oxidation of H₂ with concomitant removal of carbon species by water. Steam reforming of CH₄ can be excluded in the case of LCaCMg, as its rate was of only 1.2×10⁻¹⁰ mol/m²s at 850° C. (whereas of 1.7×10⁻⁹ and 1.1×10⁻⁸ mol/m²s for LSrC and LCaCNi respectively) ³², a low value compared to the rate of CH₄ consumption (about 4.4×10⁻⁸ mol/s). On these bases, a possible scheme for the mechanism of the reaction is depicted in FIG. 38. LSrCNi might be performing much better as its steam and CO₂ reforming activities were observed to be the highest among the series of LCs studied. As the overall polarisation losses tended to decrease as the catalytic activity increased, it is interesting to optimise the Ni content of the LSrCNi serie. In catalytic mode at least, in CH₄ combustion in 2:1:5 CH₄:O₂:He gas mixture, Stojanovic et al. ²² found that the rate increased by a factor of about 100 from x=0 to x=1 in LaCr_(1-x)Ni_(x)O₃. An optimum for our purpose takes into account the unstability of the LSrCNi matrix ³².

[0132] Further, H₂O did not seem to favour the electrocatalytic reaction in the case of LCaCMg and LSrCMg, at least at the low current densities, in accordance with previous catalytic measurements. In the contrary, CO₂ inhibited the reaction, and as in the case of the catalytic reactions, this is thought to be related to the formation of surface carbonates, as CO and CO₂ are thought to adsorb on the same catalytic sites ⁵⁹.

[0133] Finally, Sr and Ni substitution turn out to be favourable for the catalytic as well as for the electrocatalytic activities. Sr addition is required to enhance the electronic conductivity of the electrode. Sr is better than Ca from the thermodynamic point of view and also for it allows a lower expansion of the LaCrO₃. Ni substitution, reduces further this expansion

[0134] The cells were observed to be more stable when sintered at 1100° C. At higher sintering temperatures, some topotactic reactions were observed, linked with the formation of (Sr)ZrO₃ at the interface with YSZ. Further, the stability of the electrode was increased by intercalating a composite layer between the electrolyte and the electrode. The best performance was obtained with a 1 layered 78.2:21.8 La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃.+8YSZ+3 layered La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ composite anode, with a power output of 450 mW/cm² in H₂ and 300 mW/cm² in CH₄, at 875° C. The measured R_(p) in H₂ was of 0.11 Ωcm². The performance of the electrode was sustained for 136 h in methane.

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1. Use of a twice substituted lanthanide chromite as an anode material of a direct hydrocarbon fed, in particular methane fed SOFC, wherein said lanthanide chromite is substituted by Sr on A sites and by Ni or Cu on B sites.
 2. Use, as claimed in claim 1, of a Sr and Ni substituted lanthanum chromite of formula La_(1-x)Sr_(x)Cr_(1-y)Ni_(y)O₃ with the proviso that: 0.01<x<0.3 and 0.01<y<0.5 in particular with the proviso that: 0.1<x<0.2 and 0.05<y<0.2.
 3. Use of La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃ for making an anode of a SOFC.
 4. Use as claimed in claim 1, wherein said lanthanide is Praseodymium.
 5. A SOFC, with a solid electrolyte layer and at least one anode layer constituting a stratified structure, characterised in that said anode layer incorporates the twice substituted lanthanide chromite of claim 1, and in that said stratified structure comprises a composite layer comprising a major amount of said substituted lanthanide chromite and a minor amount of the material of said electrolyte layer.
 6. The SOFC of claim 5, wherein said substituted lanthanide chromite is a lanthanum chromite according to claim 2, in particular is La_(0.85)Sr_(0.15)Cr_(0.9)Ni_(0.1)O₃, and in particular that said electrolyte is YSZ or ceria.
 7. The SOFC of claims 5 or 6, wherein said stratified structure comprises one composite layer located at the interface of said anode with said electrolyte and a plurality of layers consisting of said lanthanide chromite.
 8. The SOFC of any of claims 6-7, wherein said minor amount of SOFC electrolyte is between 15% and 40% in weight, in particular about 20% in weight.
 9. The SOFC of claims 5-8, wherein said anode layer is obtained by providing said substituted lanthanide chromite as a perovskite powder, depositing at least one layer comprising said perovskite powder on a SOFC electrolyte member, thereby forming a stratified structure, and sintering said stratified structure at a temperature of between 1000° C. and 1300° C., in particular 1050° C. and 1200° C., more particularly at about 1100° C. 